Micro data flow processor design

Chang, Chih-ming

24 September 1993

Computer has evolved rapidly during the past several decades in terms of its implementation technology; it's architecture, however, has not changed dramatically since the von Neumann computer(control flow) model emerged in the 1940s. One main reason is that the performance for this kind of computers was able to satisfy the requirement of most users. Another reason maybe that the engineers who designed them are more familiar with this model. However, recent solutions to the problem of parallelizing sequential nature instructions on a von Neumann machine complicate both the compiler and the controller design. Therefore, another computer model, namely the data flow model, has regained attention since this model of computation exposes parallelism inherent in the program naturally. In terms of implementation methodology, we currently use synchronous sequential logic, which is clock controlled for synchronization within circuits. This design philosophy becomes hard to follow due to the occurrence of clock skew as the clock frequency goes higher and higher. One way to eliminate these clock related problems is to use the self-timed(asynchronous) implementation methodology. It features advantages such as free of clock-skew, low power consumption, composibility and so forth. Since data flow(data driven) computation model provides the execution of instructions asynchronously, it is natural to implement a data flow processor using self-timed circuits. In this thesis, micro pipelines, one of the self-timed implementation methodology, is used to implement a preliminary version of general purpose static data flow processor. Some interesting observations will be addressed in this thesis. An example program of general difference recursive equation is given to test the correctness and performance of this processor. We hope to gain more insight on how to design and implement self-timed systems in the future. / Graduation date: 1994

Data flow computing

Asynchronous circuits

Design of an asynchronous third-order finite impulse response filter

Oren, Joel A.

08 February 1994

With the increased demand for complex digital signal processing systems, real-time signal processing requires higher throughput systems. In the past, the throughput has been increased by increasing the clock rates, but synchronization can become increasingly more difficult. Recently there has been renewed interest in designing asynchronous digital systems. In an asynchronous system, there is no global clock, and all modules communicate through handshaking. In this thesis we demonstrate an implementation of an FIR filter using asynchronous digital circuit techniques. These asynchronous design techniques are used to test whether a practical signal processing filter can be implemented with asynchronous logic. A third-order four-bit filter is developed and simulated with SPICE, comparing favorably with other available technologies in speed and power consumption. Although in practice 8-16 bits are needed, this work is sufficient to demonstrate the feasibility of asynchronous circuits for filtering applications. A chip is laid out in 2 micron CMOS, and testing shows that it has a speed-power product comparable with asynchronous designs fabricated by others. / Graduation date: 1994

Digital filters (Mathematics)

Asynchronous circuits

Delay-insensitive ternary logic (DITL)

Parameswaran Nair, Ravi Sankar,

January 2007

Thesis (M.S.)--University of Missouri--Rolla, 2007. / Vita. The entire thesis text is included in file. Title from title screen of thesis/dissertation PDF file (viewed November 27, 2007) Includes bibliographical references (p. 55-56).

Generic algorithms and NULL Convention Logic hardware implementation for unsigned and signed quad-rail multiplication

Mallepalli, Samarsen Reddy,

January 2007

Thesis (M.S.)--University of Missouri--Rolla, 2007. / Vita. The entire thesis text is included in file. Title from title screen of thesis/dissertation PDF file (viewed November 27, 2007) Includes bibliographical references (p. 66-67).

Asynchronous nanowire crossbar architecture for manufacturability, modularity and robustness

Bonam, Ravi Kiran,

January 2008

Thesis (M.S.)--Missouri University of Science and Technology, 2008. / Vita. The entire thesis text is included in file. Title from title screen of thesis/dissertation PDF file (viewed April 28, 2008) Includes bibliographical references.

Asynchronous control circuit design and hazard generation : inertial delay and pure delay models /

Tabrizi, Nozar.

January 1997

Thesis (Ph.D.) -- University of Adelaide, Dept. of Electrical and Electronic Engineering, 1997. / Bibliography: leaves 158-167.

Learning, probabilistic, and asynchronous technologies for an ultra efficient datapath

Marr, Bo.

January 2009

Thesis (Ph.D)--Electrical and Computer Engineering, Georgia Institute of Technology, 2010. / Committee Chair: Paul Hasler; Committee Co-Chair: David V. Anderson. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Simulation and modeling of substrate noise generation from synchronous and asynchronous digital logic circuits /

Hanken, Christopher.

January 1900

Thesis (M.S.)--Oregon State University, 2008. / Printout. Includes bibliographical references (leaves 57-59). Also available on the World Wide Web.

Circuitos assíncronos na plataforma FPGA

Mocho, Renato Ubiratan Reis

January 2006

Os circuitos digitais cada vez mais são exigidos quanto ao desempenho e modularidade nos processos dos dias atuais. Para resolver estes processos, o comércio utiliza largamente circuitos digitais síncronos, que se baseiam no controle do sincronismo através de um relógio central. Esses circuitos, apesar de serem de fácil implementação e terem uma metodologia já conhecida, apresentam limitações quando se considera a distribuição dos sinais de sincronismo, a interferência do meio e os possíveis atrasos. Os circuitos assíncronos apresentam uma solução natural a essas exigências, uma vez que, possuem independência do sinal do relógio e toda sua construção é modular. Este trabalho apresenta um estudo comparativo de alguns estilos de projetos para construção de circuitos assíncronos utilizando dispositivos programados por lógica, PLDs, utilizando ferramentas de síntese lógica comerciais para circuitos síncronos. Esses circuitos assíncronos são descritos em VHDL para as células Muller, elementos M de N, registrador assíncrono, somadores e circuitos mais complexos em anel assíncrono e implementados em CPLDs e FPGAs. Os circuitos mais complexos são construídos em quatro estilos de projeto para os circuitos dos somadores: Descrição comportamental com indicação forte do sinal, DIMS, NCL e derivação a partir de circuito combinacional síncrono. Através dessa avaliação foi possível verificar as tendências do custo de elementos de programação e atrasos para realização de cálculos, frente aos circuitos síncronos similares. / This work presents a study about the implementation of asynchronous circuits on programmable devices platform. It investigates four different ways of implementing asynchronous circuits, including implementation of several different circuits in platforms provided by three different manufacturers. The implemented asynchronous circuits have a very poor performance when compared to their synchronous counterpart. However, this was expected as the platforms used were developed to be used with synchronous designs. The contributions of this work are in the following areas. First, it was described in detail how to implement VHDL code for self-timed designs. Second, different design were implemented to test the VHDL descriptions in the chosen platforms. Third, by comparing four different asynchronous styles, it is possible to find a style that is the more adequate for use in current FPGAs. Fourth, by analyzing the results obtained, it was possible to derive some conclusions on why asynchronous designs are so costly for these platforms and derive some suggestions to be used in the implementation of asynchronous FPGAs.

Microeletrônica

Fpga

Asynchronous circuits

VHDL

Implementation

Circuitos assíncronos na plataforma FPGA

Mocho, Renato Ubiratan Reis

January 2006

Os circuitos digitais cada vez mais são exigidos quanto ao desempenho e modularidade nos processos dos dias atuais. Para resolver estes processos, o comércio utiliza largamente circuitos digitais síncronos, que se baseiam no controle do sincronismo através de um relógio central. Esses circuitos, apesar de serem de fácil implementação e terem uma metodologia já conhecida, apresentam limitações quando se considera a distribuição dos sinais de sincronismo, a interferência do meio e os possíveis atrasos. Os circuitos assíncronos apresentam uma solução natural a essas exigências, uma vez que, possuem independência do sinal do relógio e toda sua construção é modular. Este trabalho apresenta um estudo comparativo de alguns estilos de projetos para construção de circuitos assíncronos utilizando dispositivos programados por lógica, PLDs, utilizando ferramentas de síntese lógica comerciais para circuitos síncronos. Esses circuitos assíncronos são descritos em VHDL para as células Muller, elementos M de N, registrador assíncrono, somadores e circuitos mais complexos em anel assíncrono e implementados em CPLDs e FPGAs. Os circuitos mais complexos são construídos em quatro estilos de projeto para os circuitos dos somadores: Descrição comportamental com indicação forte do sinal, DIMS, NCL e derivação a partir de circuito combinacional síncrono. Através dessa avaliação foi possível verificar as tendências do custo de elementos de programação e atrasos para realização de cálculos, frente aos circuitos síncronos similares. / This work presents a study about the implementation of asynchronous circuits on programmable devices platform. It investigates four different ways of implementing asynchronous circuits, including implementation of several different circuits in platforms provided by three different manufacturers. The implemented asynchronous circuits have a very poor performance when compared to their synchronous counterpart. However, this was expected as the platforms used were developed to be used with synchronous designs. The contributions of this work are in the following areas. First, it was described in detail how to implement VHDL code for self-timed designs. Second, different design were implemented to test the VHDL descriptions in the chosen platforms. Third, by comparing four different asynchronous styles, it is possible to find a style that is the more adequate for use in current FPGAs. Fourth, by analyzing the results obtained, it was possible to derive some conclusions on why asynchronous designs are so costly for these platforms and derive some suggestions to be used in the implementation of asynchronous FPGAs.

Microeletrônica

Fpga

Asynchronous circuits

VHDL

Implementation